CA2662614C - Development and characterization of novel proton conducting aromatic polyether type copolymers bearing main and side chain pyridine groups - Google Patents
Development and characterization of novel proton conducting aromatic polyether type copolymers bearing main and side chain pyridine groups Download PDFInfo
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Abstract
Description
CONDUCTING AROMATIC POLYETHER TYPE COPOLYMERS BEARING
MAIN AND SIDE CHAIN PYRIDINE GROUPS
FIELD OF INVENTION
[0001] This invention is related to the development of new aromatic copolymers bearing main and side chain polar pyridine units. Characterization of all prepared polymer materials, was performed using size exclusion chromatography, thermal and mechanical analysis. The copolymers present excellent film forming properties, high glass transition temperature up to 270 C and high thermal and oxidative stability up to 480 C. The polar pyridine groups throughout the polymeric chains enable high acid uptake (800 wt%) resulting in highly ionic conductive membranes in the conductivity range of 10-2 S/cm. The combination of the above mentioned properties confirm the potential of the new prepared materials to be used as electrolytes in high temperature PEM fuel cells.
BACKGROUND INFORMATION
The membrane is one of the key components in the design of improved polymer electrolyte membrane fuel cells. It has three main functions as electrolyte medium for ion conduction and electrode reactions, as a barrier for separating reactant gases, and as the support for electrode catalysts. An applicable PEMFC membrane should possess high ionic conductivity, low electronic conductivity, good chemical, thermal and oxidative stability as well good mechanical properties. Current technologies are based on sulfonated membranes, such as Nation, although it is not suitable at high temperatures or under low relative humidity conditions. Also, its methanol crossover and high cost have still to be overcome for commercialization. Current research on PEMFCs is focused on the optimization of a device working at operational temperatures above 100 C and at very low humidity levels. Operation of the fuel cells at elevated temperatures has the benefits of reducing CO poisoning of the platinum electrocatalyst and increased reaction kinetics. In this respect, new polymeric materials have been synthesized in order to replace Nafion. One of the most successful high temperature polymer membranes developed so far is the phosphoric acid-doped Polybenzimidazole (PBI). Apart from high thermal stability and good membrane-forming properties, PBI contains basic functional groups which can easily interacts with strong acids, such as H3PO4 and H2SO4, allowing proton migration along the anionic chains. Even though PRI membranes show high proton conductivity at high temperature (>100 C) under low relative humidity conditions and have a high CO tolerance, they exhibit low oxidative stability and moderate mechanical properties. Beside Polybenzimidazole (PBI), there is a significant research effort nowadays towards the development of some novel polymeric materials, which fulfill the prerequisites for use in high temperature PEMFCs. Poly(2,5-benzimidazole) (ABPBI) is an alternative benzimidazole type polymer with thermal stability and conducting properties as good as those of PBI. On the other hand, high-temperature aromatic polyether type copolymers containing basic groups like PBI enable formation or complexes with stable acids and exhibit high thermal, chemical stability and good conducting properties in order to be used in high temperature PEMFCs.
At the current state of the technology, prior efforts together with current approaches have to be tempered with the ability to translate developments in this regard to mass manufacturability while keeping reproducibility (batch vs. continuous) and cost in perspective. Depending on the deposition methods used, the approach towards lowering noble metal loading can be classified into five broad categories, (i) thin film formation with carbon supported electrocatalysts, (ii) pulse electrodeposition of noble metals (Pt and Pt alloys), (iii) sputter deposition (iv) pulse laser deposition, and (v) ion-beam deposition. While the principal aim in all these efforts is to improve the charge transfer efficiency at the interface, it is important to note that while some of these approaches provide for a better interfacial contact allowing for efficient movement of ions, electrons and dissolved reactants in the reaction zone, others additionally effect modification of the electrocatalyst surface (such as those rendered via sputtering, electrodeposition or other deposition methods).
Among the limitations of this approach are problems with controlling the Pt particle size (with loading on carbon in excess of 40%), uniformity of deposition in large scale production and cost (due to several complex processes and /or steps involved).
Developments in the pulse algorithms and cell design have enabled narrow particle size range (2-4 nm) with high efficiency factors and mass activities for oxygen reduction. Though attractive, there are concerns on the scalability of this method for mass scale manufacturing.
containing conventional gas diffusion electrode. Such an approach (Mukerjee, Srinivasan et at.
1993) exhibited a boost in performance by moving part of the interfacial reaction zone in the immediate vicinity of the membrane. Recently, Hirano et al. (Hirano, Kim et at.
1997) reported promising results with thin layer of sputter deposited Pt on wet proofed non catalyzed gas diffusion electrode (equivalent to 0.01 mgpt/cm2) with similar results as compared to a conventional Pt/C (0.4 mgpt/cm2) electrode obtained commercially. Later Cha and Lee (Cha and Lee 1999), have used an approach with multiple sputtered layers (5 nm layers) of Pt interspersed with Nafion3-carbon-isopropanol ink, (total loading equivalent of 0.043 mgpt/cm2) exhibiting equivalent performance to conventional commercial electrodes with 0.4 mgp1/cm2. Huag et al.
(Haug 2002) studied the effect o substrate on the sputtered electrodes.
Further, O'Hare et al., on a study of the sputter layer thickness has reported best results with a 10 nm thick layer. Further, significant advancements have been made with sputter deposition as applied to direct methanol fuel cells (DMFC) by Witham et al.
(Witham, Chun et al. 2000; Witham, Valdez et al. 2001) wherein several fold enhancements in DMFC performance was reported compared to electrodes containing unsupported PtRu catalyst. Catalyst utilization of 2,300 mW/mg at a current density of 260 to 380 mA/cm2 was reported (Witham, Chun et al. 2000; Witham, Valdez et al.
2001). While the sputtering technique provides for a cheap direct deposition method, the principal drawback is the durability. In most cases the deposition has relatively poor adherence to the substrate and under variable conditions of load and temperature, there is a greater probability of dissolution and sintering of the deposits.
1999).
structures including overhang and hollow structures have also been recently reported (Hoshino, Watanabe et at. 2003). Use of dual anode ion source for high current ion beam applications has also been reported recently (Kotov 2004), where benefits for mass production environment is discussed.
SUMMARY OF THE INVENTION
The invention further relates to the preparation and application of MEA on PEMFC
type single cells. The combination of the above mentioned properties indicate the potential of the newly prepared materials to be used as electrolytes in high temperature PEM fuel cells.
BRIEF DESCRIPTION OF THE DRAWINGS
Figure 1 shows temperature dependence of the storage (E') and loss (E") modulus of copolymer dPPy(50)coPPyPES before (M) and after (o) the treatment with H202;
Figure 2 shows temperature dependence of the storage (E') and loss (E") modulus of copolymer dPPy(50)coPPyPO before (II) and after (o) the treatment with H202;
Figure 3 shows temperature dependence of the storage (E') and loss (E") modulus of copolymer dPPy(10)coPPyPO before (IN) and after (o) the treatment with H202;
Figure 4 shows thermogravimetric analysis of dPPy(50)coPPyPES before (111) and after (o) the treatment with H202;
Figure 5 shows time dependence of doping level (wt%) of dPPy(40)coPPyPES at 25 C (M) and 50 C (o) and of dPPy(50)coPPyPES at 25 C
(Eh) and 50 C (0);
Figure 6 shows time dependence of doping level (wt%) of dPPy(10)coPPyPO(o), dPPy(20)coPPyPO(M), dPPy(30)coPPyP0( = ), dPPy(40)coPPyPO (0), dPPy(50)coPPyPO (fib) at 25 C;
Figure 7 shows time dependence of doping level (wt%) of PPy(10)coPPyPO(o), dPPy(20)coPPyPO(M), dPPy(30)coPPyPO (A), dPPy(40)coPPyPO (0), dPPy(50)coPPyPO (.) at 50 C;
Figure 8 shows doping level dependence of ionic conductivity of dPPy(50)c0PPyPES at room temperature;
Figure 9 shows temperature dependence of ionic conductivity of acid doped dPPy(50)coPPyPES with a doping level 480wt% H3PO4 and relative humidity 60%;
DEFINITIONS
DETAILED DESCRIPTION OF THE INVENTION
Polymer Membrane Electrolyte
--(0 0--X) =
n R= ¨0 --eN --4IND
N 9 N 9 \ 9 s NI 9 N
X= = SO2, co ' 111 = F F F F
ip , Co - , 4IkF F F F
A= ¨CH2 ,¨CF2 ,¨phenyl , none Structure 1 /n R= ¨¨Cu N N " N
X= 1r S02. co-Q¨, 11/= , F F F F
Structure 2
H
O OH
wherein R is selected from the group consisting of ¨N
< 5 __ \ 9 and ---( N
or a salt thereof. According to various embodiments, the aromatic difluoride is bis-(4-fluorophenyl)sulfone, bis-(4-fluorophenyl)phenylphosphine oxide, 4,4'-difluorobenzophenone, or decafluorobipheynyl.
wherein R is selected from the group consisting of R= 5 ¨N
0 5 N9 9 and ---(N-) // N¨/
or a salt thereof, the process comprising coupling a compound of the formula:
YO OY
wherein X is a metal or metalloid atom or an electrophile or leaving group, and Y is 11 or a protecting group, with a compound selected from:
¨N
Z _______________ ( N Z¨( and N-in which Z is a metal or metalloid atom or an electrophile or leaving group, in the presence of a metal containing catalyst. According to preferred embodiments, the coupling reaction is a Suzuki cross coupling reaction of an aryl-boronic acid with an aryl-halide catalyzed by a palladium(0) complex.
/ \ N
_ \--, . = = so2 .
N
x Y
\ /
copolymer 1: dPPy(x)coPPyPES
/ \N
( . 11 = 111 5? lik = le \--/ Ilik 111 52 411.
N
0 x Ill Y
\ /
copolymer 2: dPPy(x)coPPyPO
/ \N
--(0 11 0 11 SO2 11, n N\ /
homopolymer 1: dPPyPES
/ \N
-(o. 0 Ill A lip -N\/ 40 n homopolymer 2: dPPyPO
depending on the structure and the copolymer composition. The oxidative stability of the copolymers can be examined with dynamic mechanical analysis and thermogravimetric analysis. As shown in Figures 1-3, the copolymers retain their flexibility and mechanical integrity both before and after treatment. The chemical, thermal and oxidative stability of the copolymers can be examined using the Fenton's test. Membrane samples are immersed into 3wt% H202 aqueous solution containing 4ppm FeC12x4H20 at 80 C for 72h. Figure 4 illustrates the weight of thy samples before and after experimentation. As shown, the blend membranes retain their mechanical integrity and their high thermal stability. As shown in Figures 5-7, in order to obtain the maximum doping level, the membranes are immersed into 85wt%
phosphoric acid solution at different temperatures and for different doping times depending on the membrane composition. The wet membranes are wiped dry and quickly weighed again. The acid uptake of membranes is defined as the weight percent of the acid per gram of the copolymer. As the doping temperature increases the phosphoric acid doping level also increases reaching plateau values of around 800wt% H3PO4 doping level for the copolymer 1 at 50 C. Figure 8 illustrates the doping dependence of the conductivity of a sample of copolymer 1 doped with phosphoric acid. Figure 9 illustrates the effect of temperature of the conductivity of copolymer 1 doped with 480 wt% phosphoric acid. As shown, the conductivity increases as temperature increases. At 160 C the conductivity reached a value of 5.9*10-2 S/cm even at room temperature.
The method for implementing of membrane electrode assembly includes (a) a gas diffusion and current collecting electrode component, (b) a reaction layer component comprising of a catalyst and ion conducting elements in conjunction with crosslinkers, and (c) Pt alloy electrocatalysts for enhanced CO tolerance and oxygen reduction reaction activity.
The Gas Diffusion Electrode Component
The choice of carbon blacks used in this layer range from Ketjen black to turbostratic carbons such as Vulcan XC-72 (Cabot Corp, USA) with typical surface areas in the range of 250 to 1000 m2/gm. The deposition can be applied with a coating machine such as Gravure coaters from Euclid coating systems (Bay City, MI, USA). A
slurry composition comprising of carbon black and PTFE (poly tetrafluoro ethylene) in aqueous suspension (such as Dupont TFE-30, Dupont USA) is applied to a set thickness over the carbon paper or cloth substrate with the aid of the coating machine.
Typical thickness of 50-500 microns is used. Pore forming agents are used to prepare this diffusion layer on the carbon conducting paper or cloth substrate.
Careful control of the pore formers which consist of various combinations of carbonates and bicarbonates (such as ammonium and sodium analogs) affords control of gas access to the reaction zone. This is achieved by incorporation of these agents in the slurry mixture comprising of carbon black and PTFE suspension. Typical porosity rendered in this fashion differs from anode and cathode electrode and is in the range of 10-90%. Coated carbon substrates containing the gas diffusion layers are sintered to enable proper binding of components. This can be achieved using thermal treatment to temperatures significantly above the glass transition point for PTFE, usually in the range 100 to 350 C for 5 to 30 minutes.
Formation of Reaction Layer Comprising of Electrocatalyst and Ion Conducting Components
2003; Murthi, Urian et al. 2004; Teliska, Murthi et al. 2005). This renders the surface largely bare for molecular oxygen adsorption and subsequent reduction.
Lowering anion adsorption such as phosphate anion for a phosphoric acid based ion conductor enables enhanced oxygen reduction kinetics. In addition to choice of alloys, the use of perflurosulfonic acids either alone or as a blend with other ion conductors are used to enhance oxygen solubility. It is well known that oxygen solubility is approximately eight times higher in these fluorinated analogs as compared to phosphoric acid based components (Zhang, Ma et al. 2003). The electrocatalyst can be obtained from commercial vendors such as Columbian Chemicals (Marrietta, GA, USA), Cabot Superior Micro-powders (Albuquerque, NM, USA). The typical weight ratio of the catalyst on carbon support being 30-60% of metal on carbon.
within choice of each component enabling a total catalyst loading 0.3 to 0.4 mg of Pt or Pt alloy/cm2. The application of the slurry is achieved via a combination or exclusive application of calendaring, screen printing or spraying.
Formation of membrane electrode assembly
Example 1 Synthesis of 2,5-di(Pyridin-3-yl)benzene-1,4-diol
Then the mixture is cooled again at -80 C and trimethyl borate is slowly added. The mixture is lifted under stirring at room temperature for 24 hours. Distilled water is added for 3 hours in order to hydrolyze the boric ester groups. The organic layer is then separated and the organic solvent is removed under reduced pressure. The residue is treated with Hexane for 24 hours. The product 2,5-(Tetrahydro-2H-pyrany1(1)acid)phenyl diboronic acid is filtered and dried at 30 C under vacuum and the THP-protected diol is obtained at 55% yield.
The soluble product is filtered in order to remove by-products. Deprotonation is performed using 2M Na2CO3 and sinking of the product. Filtration, washing with water and cold hexane, and drying at 50 C under vacuum results in 2,5-di(Pyridin-3-yl)benzene-1,4-diol in 60% yield.
One of the synthetic procedures which is followed for the synthesis of the monomer is given below.
Br 0 Br HO 11/ OH ___________________________________________ Br Br Br B(OH)2 nBuLii B(OMe)3 THPO . OTHP _________________________ THPO . OTHP
Br (H0)2B
/ \ N
B(OH)2 THPO 0 OTHP + Br <Na2CO3 ____________________________________________ - THPO * OTHP
¨11 pd(PPh3)4 (H0)2B ___ N\ /
THF / Me0H
THPO la OTHP ________________________ - HC1 HO * OH
N\ /
Example 2 Synthesis of copolymer dPPy(50)c0PPyPES
for 48 hours. The obtained viscous product is diluted in DMF and precipitated in a 10-fold excess mixture of Me0H, washed with H20 and Hexane, and dried at 80 C under vacuum. The same procedure is followed to produce copolymer dPPy(40)coPPyPES, by varying the feed ratio of the two diols.
Example 3 Synthesis of copolymer dPPy(50)coPPyPO
under vacuum. The same procedure is followed to produce copolymers with different 2,5-di(Pyridin-3-yObenzene-1,4-diol molar percentage, by varying the feed ratio of the two diols.
Example 4 Synthesis of homopolymer dPPyPES
The mixture is degassed under Ar and stirred at 150 C for 24 hours, and then stirred at 180 C for 4 days. The obtained product is precipitated in a 10-fold excess mixture of Me0H, washed with H20 and Hexane, and dried at 80 C under vacuum. The same procedure is followed to produce homopolymers with different 2,5-di(Pyridin-3-yl)benzene-1,4-diol molar percentage, by varying the feed ratio of the two reactants.
Example 5 Synthesis of homopolymer dPPyPO
=
_ Example 6 Membrane Electrode Assembly
Polarization measurements were conducted at 170-200 C, 1.5 bars, H2/Air (2:2 stoichiometric flow). Steady state current was also monitored for stability studies up to 400hrs at a constant potential of 0.5V vs. RHE.
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Acta 48: 1845-1859.
Development and characterization of novel proton conducting aromatic polyether type copolymers bearing main and side chain pyridine groups Maria Geormezi, Nora Gourdoupi Advent Technologies, Patras Science Park, Patras 26504, Greece
Claims (9)
wherein R is selected from the group consisting of:
X is selected from the group consisting of:
Y is selected from the group consisting of:
A is selected from the group consisting of-CH2,-CF2, -phenyl and none; and n and m are positive integers, or a salt thereof.
wherein R is selected from the group consisting of:
X is selected from the group consisting of:
and n is a positive integer, or a salt thereof.
wherein R is selected from the group consisting of or a salt thereof;
and wherein the aromatic difluoride is bis-(4-fluorophenyl)sulfone, bis-(4-fluorophenyl)phenylphosphine oxide, 4,4'-difluorobenzophenone, or decafluorobipheynyl.
(a) depositing a layer of the composition of claim 8 by calendaring, screen printing or spraying on a hydrophobic layer; and (b) drying and sintering the layer deposited in step (a), thereby preparing the catalyst.
Applications Claiming Priority (3)
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| US60/843,879 | 2006-09-11 | ||
| PCT/IB2007/004485 WO2008090412A2 (en) | 2006-09-11 | 2007-09-10 | Proton conducting aromatic polyether polymers with pyridinyl side chains for fuel cells |
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| CA2662614C true CA2662614C (en) | 2015-11-24 |
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| EP (1) | EP2089377B1 (en) |
| JP (1) | JP5324445B2 (en) |
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| JP3228182B2 (en) | 1997-05-29 | 2001-11-12 | 株式会社日立製作所 | Storage system and method for accessing storage system |
| US6684209B1 (en) | 2000-01-14 | 2004-01-27 | Hitachi, Ltd. | Security method and system for storage subsystem |
| US7842775B2 (en) * | 2006-09-11 | 2010-11-30 | Advent Technologies Sa | Development and characterization of novel proton conducting aromatic polyether type copolymers bearing main and side chain pyridine groups |
| US7842734B2 (en) * | 2006-09-12 | 2010-11-30 | Advent Technologies Sa | Poly(arylene ether) copolymers containing pyridine units as proton exchange membranes |
| JP7146080B2 (en) * | 2018-10-20 | 2022-10-03 | カウンシル オブ サイエンティフィック アンド インダストリアル リサーチ | Polymer layered hollow fiber membranes based on poly(2,5-benzimidazole), copolymers, and substituted polybenzimidazoles |
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| DE69528462T2 (en) * | 1995-11-09 | 2003-02-06 | Mississippi Polymer Technologies, Inc. | Polymers with heterocyclic side groups |
| JP3456378B2 (en) * | 1997-08-21 | 2003-10-14 | 株式会社村田製作所 | Solid oxide fuel cell |
| DE10019732A1 (en) * | 2000-04-20 | 2001-10-31 | Univ Stuttgart Lehrstuhl Und I | Acid base polymer membrane for use as fuel cells membrane for e.g. hydrogen or direct methanol fuel cells, comprises at least one polymeric acid or polymer base with specified proton conductivity |
| DE10246461A1 (en) * | 2002-10-04 | 2004-04-15 | Celanese Ventures Gmbh | Polymer electrolyte membrane containing a polyazole blend for use, e.g. in fuel cells, obtained by processing a mixture of polyphosphoric acid, polyazole and non-polyazole polymer to form a self-supporting membrane |
| JP2005108770A (en) * | 2003-10-01 | 2005-04-21 | Matsushita Electric Ind Co Ltd | Method for producing electrolyte membrane electrode assembly |
| CN100521329C (en) * | 2005-01-14 | 2009-07-29 | 松下电器产业株式会社 | Stack for fuel cell, and fuel cell |
| US7842733B2 (en) * | 2006-09-11 | 2010-11-30 | Advent Technologies Sa | Aromatic polyether copolymers and polymer blends and fuel cells comprising same |
-
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| WO2008090412A2 (en) | 2008-07-31 |
| JP2010502810A (en) | 2010-01-28 |
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| EP2089377B1 (en) | 2013-04-10 |
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